KR20210098392A - Paraffin coating method of amminium nitrate fule oil - Google Patents

Abstract

The present invention relates to a paraffin coating method of ammonium nitrate fuel oil, and more specifically, to a paraffin coating method of an ammonium nitrate fuel oil which can coat a surface of ammonium nitrate fuel oil with paraffin to prevent the generation of static electricity and to reduce the moisture absorption of an explosive in water or in a bedrock with water. The paraffin coating method of ammonium nitrate fuel oil of the present invention comprises the steps of: (S10) preparing a paraffin coating solution (2) by injecting solid paraffin into a heating device (10) having a temperature of 47℃ to 70℃; and (S20) injecting and stirring the ammonium nitrate fuel oil and the paraffin coating solution to coating devices (20, 20-1) connected to the heating device (10), respectively, to coat the surface of the ammonium nitrate fuel oil (1) with paraffin (2).

Description

Paraffin coating method of anpo explosives {PARAFFIN COATING METHOD OF AMMINIUM NITRATE FULE OIL}

The present invention relates to a paraffin coating method of an intracellular explosive, and more particularly, an intracellular explosive that can be coated with paraffin on the surface of the intraocular explosive to prevent the generation of static electricity and reduce the moisture absorption of the explosive in water or in the presence of water. It relates to the paraffin coating method of

In general, blasting (發破) refers to the destruction of objects in mines, coal mines, and civil engineering sites. Although there is blasting of concrete structures, blasting performed to destroy rocks in mines and quarries is the largest and the largest. In rock blasting, it is common to make a hole in the rock and load it with explosives to blast it. Today's blasting work ranges from crushing large chunks of rocks to large-scale blasting of tens of thousands of tons of rocks at once.

A rock drill and a drill are used to drill a blast hole for loading explosives. In blasting, a hole with a diameter of several centimeters and a depth of several meters is usually used.

Among the various types of explosives used for such blasting, the ammonium nitrate fuel oil (ANFO) explosive is the cheapest among the explosives and has excellent stability. It is sold in small-powder-shaped explosives in sacks of a certain capacity.

The Anpo explosives contained in these sacks were transported to the construction site, then the sacks were opened, and the sacks were poured into the holes in the bedrock drilled for blasting at the construction site, and then charged and loaded on the top of the pre-charged full explosives width.

However, when using the anpo explosive directly by pouring it into the drilling hole in this way, the anpo explosive is vulnerable to water, and if there is water in the bedrock, the anpo explosive comes into contact with water, resulting in a problem that the blasting efficiency decreases and the risk increases.

(Patent Document 01) Domestic Registered Patent Publication No. 10-1022251

In order to solve the above problems, the present invention uses a coating device to coat paraffin on the surface of an infusion explosive to prevent the generation of static electricity and to reduce the moisture absorption of the explosive in water or in a bedrock where water exists. An object of the present invention is to provide a paraffin coating method.

The paraffin coating method of the ophthalmic explosive of the present invention includes the steps of preparing a paraffin coating solution (2) by injecting solid paraffin into a heating device 10 having a temperature of 47°C to 70°C (S10);

The step of coating the paraffin (2) on the surface of the ophthalmic explosive (1) by adding and stirring the ophthalmic explosive and the paraffin coating solution to the coating devices (20, 20-1) connected to the heating device (10), respectively (S20) It is characterized in that it is composed of

The present invention prevents the generation of static electricity and escapes the risk of safety accidents due to erroneous explosion because paraffin is uniformly coated on the surface of the explosive explosive, and by reducing the moisture absorption of the explosive, it is also included in the rocks under water or water. It has the effect of being able to use a wide range of explosives.

In addition, the high thermal conductivity of paraffin improves the blasting efficiency of the inner explosives, so that sufficient explosive power can be obtained by using a small amount of explosives, so it is economical and has the effect of reducing noise and vibration during blasting.

1 is a cross-sectional view of an ophthalmic explosive coated with paraffin by the paraffin coating method of the ophthalmic explosive according to the present invention;
2 and 3 are schematic diagrams of a coating device used in the paraffin coating method of the ophthalmic explosive according to the present invention.

The paraffin coating method of the ophthalmic explosive of the present invention includes the steps of preparing a paraffin coating solution by injecting solid paraffin into a heating device 10 having a temperature of 47°C to 70°C (S10);

The step of coating the paraffin (2) on the surface of the ophthalmic explosive (1) by adding and stirring the ophthalmic explosive and the paraffin coating solution to the coating devices (20, 20-1) connected to the heating device (10), respectively (S20) It is characterized in that it is composed of

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

In step (S10), the solid paraffin is liquefied using the heating device 10 .

The paraffin (or paraffin wax, paraffin wax) refers to a solid of CnH2n+2 (20 ≤ n ≤ 40), and has a melting point of about 47° C. to 64° C., and is known to be used for lubrication, insulation, and candle manufacturing.

The paraffin in the solid state is melted and heated using a heating device 10 having a temperature of 47°C to 70°C to prepare a paraffin coating solution.

In step (S20), paraffin (2) is uniformly coated on the surface of the inner explosive (1) to prevent the generation of static electricity by the paraffin (2) and moisture absorption of the explosive in water or moisture absorption area. make it possible

The ophthalmic explosive (1) is prepared by purchasing from Korea Chemical or Korea Chemical, which are explosive manufacturers, and coating devices (20, 20-1) are used to coat the paraffin (2) on the ophthalmic explosive (1).

As shown in FIG. 2 , the coating device 20 has a cylindrical first housing 21 and an upper inlet 22 formed on one side of the first housing 21 and into which the anti-explosive 1 is injected. ) and the heating device 10, the lower inlet 23 is formed in the lower part of one side of the first housing 21 and into which the paraffin coating solution is put, and the stirrer 24 installed inside the first housing 21 and an outlet 25 installed in the lower portion of the other side of the first housing 21 .

The first housing 21 is installed to be inclined downwardly from one side to the other, and the inside is maintained at a temperature of 40°C to 45°C to prevent the paraffin coating solution injected therein from solidifying.

The upper inlet 22 and the lower inlet 23 are respectively provided on the upper and lower sides of one side of the first housing 21 in the upper direction. ), while the paraffin coating solution is supplied through the heating device 10, the ophthalmic explosive and the paraffin coating solution can be injected from separate inlets.

The stirrer 24 is installed inside the first housing 21 so that the paraffin 2 is uniformly and easily coated on the internal explosive 1 injected into the inner lower part of the first housing 21 . A stirring shaft 240 installed in the longitudinal direction on the side and rotationally driven by the power of a motor and a stirring brush 241 having a brush shape on the outer periphery of the stirring shaft 24 to increase the stirring efficiency or having a rod shape A plurality of stirring blades 242 are installed to protrude in a radial form.

The stirring brush 241 or the stirring blade 242 is rotated by the stirring shaft 24, and the anti-foaming explosive 1 and the paraffin coating solution injected into the first housing 21 are evenly stirred for a certain period of time. (2) is applied evenly on the surface of the anti-foaming explosive (1) so that it can be coated.

The outlet 25 is installed at the lower end of the other side in the lower direction of the first housing 21, and while stirring inside the first housing 21, the paraffin 2 coated on the surface is discharged.

The coating device 20 is installed for on-site use in the blasting area to obtain paraffin-coated ophthalmic explosives at the site, or is installed for factories to manufacture paraffin-coated ophthalmic explosives and then packaged and distributed in the market. make it possible

On the other hand, in the case of the coating device 20 installed for a factory, a refrigeration device 30 for cooling the paraffin-coated ophthalmic explosive discharged from the coating device 20 is connected and installed.

The cooling device 30 is connected to the lower end of the outlet 25 and has a cylindrical second housing 31 installed to be inclined downwardly from the other side to one side, and a stirrer 32 installed inside the second housing 31 . ) and an outlet 33 installed in the lower portion of one side of the second housing 31 in the lower direction.

The second housing 31 is connected to the lower end of the outlet 25 installed in the first housing 21, and in order to cool the explosive explosive 1 discharged from the outlet 25, the internal temperature of -20 ℃ to -25 The paraffin (2) is cured by cooling the paraffin (2) coated on the surface of the internal explosive (1) by keeping it at a temperature of ℃, so that the paraffin (2) is evenly coated on the surface of the internal explosive (1). make it

The stirrer 32 is composed of a stirring shaft 320, a stirring brush 321, or stirring blades 322 in the same manner as the stirrer 24 installed in the coating unit 20. Explosives (1) It is possible to increase the agitation and cooling efficiency.

The outlet 33 is installed at the lower end of one side of the second housing 31 in the downward direction, and while cooling inside the second housing 31, paraffin is hardened on the surface so that the uniform coating is discharged. .

As shown in FIG. 3, the coating device 20-1 is installed inclined downward from one side to the other side and has a cylindrical first housing 21-1 having a temperature of 40°C to 45°C inside, and the An injection nozzle 22-1 that is formed on one side of the first housing 21-1 in the upper direction and sprays an explosive 1 in the interior of the first housing 21-1, and the first housing 21 -1) is composed of a stirring rod 23-1 installed in the inner central portion, and an outlet 24-1 installed in the lower portion of the other side in the lower direction of the first housing 21-1.

The first housing 21-1 maintains a temperature of 40° C. to 45° C. to prevent the paraffin coating solution supplied therein from solidifying, and the spray nozzle 22-1 is the first housing 21-1. Inject the anti-foam explosive (1) into the interior of the to be supplied as is.

The stirring rod 23-1 is connected to the heating device 10 installed on one side of the first housing 21-1, and is in the form of an internal hollow pipe so that the paraffin coating solution is supplied therein. The injection protrusions 230-1, which are rotationally driven and formed with a plurality of injection holes 231-1, so as to discharge the paraffin coating solution therein by high-pressure injection into the first housing 21-1, are provided with a stirring rod 23- It protrudes in a radial form on the outer periphery of 1) and is formed at regular intervals in the longitudinal direction.

In the stirring rod 23-1, the spraying protrusions 230-1 are rotated while the paraffin coating solution is sprayed at high pressure in each injection hole 231-1, so that the first housing ( 21-1), the paraffin coating solution can be evenly sprayed onto the surface of the intraocular explosive (1), which is supplied in a suspended state, so that the stirring efficiency of the intraocular explosive (1) and the paraffin coating solution and the coating efficiency of the paraffin can be increased.

The discharge port 24-1 is installed at the lower end of the other side in the downward direction of the first housing 21-1, and the paraffin 2 coated on the surface is discharged from the inside of the first housing 21-1. make it

A cooling device 30-1 for cooling the discharged paraffin-coated ophthalmic explosive is connected to the coating device 20-1 and installed.

The cooling device 30-1 is connected to the lower end of the outlet 24-1 and includes a cylindrical second housing 31-1 and a second housing 31-1 that are installed to be inclined downward from the other side to one side. It is composed of a stirring shaft 32-1 installed therein and an outlet 33-1 installed in a lower portion of one side of the second housing 31-1 in the downward direction.

The second housing (31-1) is connected to the lower end of the outlet (24-1) installed in the first housing (21-1), and cools the explosive explosive (1) discharged from the outlet (24-1). In order to make the paraffin coating solution hardened by cooling the paraffin coating solution coated on the surface of the internal explosive (1) by maintaining the internal temperature at a temperature of -20 °C to -25 °C, the paraffin (2) is applied to the surface of the internal explosive (1). To maintain an even and uniform coating state.

The stirring shaft 32-1 is rotated by the power of a motor in the form of a hollow pipe, and the internal temperature of the second housing 31-1 is -20 to -25°C from -20°C. A stirring protrusion 320-1 having a plurality of through-holes 321-1 through which cooling air at a temperature of -25°C is discharged radially protrudes from the outer periphery of the stirring shaft 32-1, and a plurality of them are formed in the longitudinal direction. It is formed so that it is possible to increase the stirring and cooling efficiency of the internal explosives inside the second housing (31-1).

The outlet 33-1 is installed at the lower end of one side of the second housing 31-1 in the downward direction, and as it cools inside the second housing 31-1, paraffin is cured on the surface to obtain a uniform coating. It causes the explosives to be discharged.

Paraffin coated evenly and uniformly on the surface by the coating device (20, 20-1) as described above suppresses the generation of static electricity by paraffin, This permeation can be reduced, so that it is possible to effectively reduce the erroneous explosion caused by static electricity and the absorption of explosives.

In addition, paraffin has high thermal conductivity so that the explosive power of an explosive can be transferred to other adjacent explosives quickly, so that the blasting efficiency is improved and sufficient blasting effect can be obtained even with a small amount of explosives.

As described above, preferred embodiments of the present invention have been posted in the present specification and drawings, and although specific terms are used, these are only used in a general sense to easily explain the technical content of the present invention and help the understanding of the present invention. , it is not intended to limit the scope of the present invention. It will be apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

1: Anpo explosives
2: Paraffin
10: heating device
20: coating device
30: cooling device
20-1: coating device
30-1: cooling device

Claims (7)

preparing a paraffin coating solution by putting paraffin in a solid state into a heating device 10 having a temperature of 47° C. to 70° C. (S10);
The step of coating the paraffin (2) on the surface of the ophthalmic explosive (1) by adding and stirring the ophthalmic explosive and the paraffin coating solution to the coating devices (20, 20-1) connected to the heating device (10), respectively (S20) Paraffin coating method of anpo explosives, characterized in that it consists of. The method according to claim 1,
The coating device 20 is installed inclined downwardly from one side to the other side and is formed on a first cylindrical housing 21 having an internal temperature of 40 to 45° C. an upper inlet 22 that is used, a lower inlet 23 formed on one side of the lower portion of the first housing 21 and connected to the heating device 10 to receive a paraffin coating solution, and an inner lower side of the first housing 21 A stirrer 24 that is installed to agitate the ophthalmic explosives and paraffin injected inside to make the ophthalmic explosives coated with paraffin, and an outlet ( 25), the paraffin coating method of the ophthalmic explosive, characterized in that it consists of. 3. The method according to claim 2,
The coating device 20 has a cylindrical second housing 31 connected to the lower end of the outlet 25, installed inclined downward from the other side to one side, and having an internal temperature of -20°C to -25°C, and a second housing (31) A cooling device having a stirrer 32 installed on the lower side of the inside to cool and agitate the paraffin-coated ophthalmic explosive, and an outlet 33 installed at the lower part of one side of the second housing 31 to discharge the cooled ophthalmic explosive. (30) Paraffin coating method of the ophthalmic explosive, characterized in that it is installed. 3. The method according to claim 2,
The agitator (24,32) is a paraffin coating method of an explosion explosive, characterized in that a plurality of brush-shaped stirring brushes (241, 321) or rod-shaped stirring blades (242, 322) are radially installed on the outer periphery of the stirring shaft (240, 320). . The method according to claim 1,
The coating device 20-1 is installed to be inclined downward from one side to the other side and has a cylindrical first housing 21-1 having an internal temperature of 40°C to 45°C, and one side of the first housing 21-1. It is formed and is connected to the injection nozzle 22-1 for spraying the inner explosives into the first housing 21-1, and the heating device 10 installed on one side of the first housing 21-1, so that the paraffin inside is connected to the inside. A spraying protrusion 230-1 is installed in the inner center of the first housing 21-1 to supply a coating solution and sprays the paraffin coating solution to the anti-foaming explosive, and a plurality of injection holes 231-1 are formed on the outer periphery. It characterized in that it is composed of a stirring rod 23-1 formed to protrude radially, and an outlet 24-1 installed in the lower part of the other side of the first housing 21-1 through which paraffin-coated anti-explosives are discharged. Paraffin coating method of anpo explosives. 6. The method of claim 5,
The nose device 20-1 has a cylindrical second housing 31-1 connected to the lower end of the outlet 24-1, installed inclined downward from the other side to one side, and having an internal temperature of -20°C to -25°C; A stirring shaft 32-1 installed in the inner central portion of the second housing 31-1 and having a plurality of stirring protrusions 320-1 radially formed on the outer periphery, and the second housing 31-1 A paraffin coating method of an anti-explosive, characterized in that a cooling device (30-1) having an outlet (33-1) through which the cooled explosive is discharged by being installed in the lower part of one side. 7. The method of claim 6,
The stirring shaft 32-1 has a hollow pipe shape, and cooling air of -20°C to -25°C is supplied to the inside, and the cooling air is discharged to the inside of the second housing 31-1. The paraffin coating method of the ophthalmic explosive, characterized in that a plurality of through holes (321-1) are formed in the protrusion (320-1).

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